2018 Spring — PHYS 315 [8255]
Book: Peter Schneider Extragalactic astronomy and cosmology ISBN-13: 978-3642540820 ISBN-10: 3642540821
3 credits
Pre-requisites: PHYS122 or PHYS 122H with grade C or higher. A good grade in either PHYS 105 or PHYS 304 will be of some advantage, but not required.
Material: scientific calculator
Instructor: Professor T.J.Turner Office Hours, M,W,F by appointment only in PHYS 412 Phone 410 455 1978 email [email protected]
Overview: The formation, constituents, structure and dynamics of galaxies. Galaxy types. Hierarchy of structure. AGN. Dark matter. Distance estimation.
Course objectives: Main objectives are for students to become familiar with the characteristics and components of the various galaxy types in the known universe.
Detailed Objectives: By the end of the course students will be able to -describe the various types of galaxies found in the universe -describe some of the observing techniques used in the study of galaxies -understand the components of our Galaxy, the Milky Way -understand the importance of supermassive black holes in galaxy nuclei -understand the importance of galaxy studies to cosmology
Grading: Final Exam 20% 2 Mid term Exams 20% each Telescope attendance 10% Class attendance 10% Homework 20%
The course will include (provisional topics, may be revised in the details):
The Milky Way as a galaxy o Galactic coordinates o Determination of distances within our Galaxy + Trigonometric parallax + Proper motions + Moving cluster parallax + Photometric distance; extinction and reddening + Spectroscopic distance + Distances of visual binary stars + Distances of pulsating stars o The structure of the Galaxy + The Galactic disk: Distribution of stars + The Galactic disk: chemical composition and age + The Galactic disk: dust and gas + Cosmic rays + The Galactic bulge + The visible halo + The distance to the Galactic center o Kinematics of the Galaxy + Determination of the velocity of the Sun + The rotation curve of the Galaxy o The Galactic microlensing effect: The quest for compact dark matter + The gravitational lensing effect I + Galactic microlensing effect + Surveys and results + Variations and extensions o The Galactic center + Where is the Galactic center? + The central star cluster + A black hole in the center of the Milky Way + Flares from the Galactic center + The proper motion of Sgr A* + Hypervelocity stars in the Galaxy
The world of galaxies o Classification + Morphological classification: The Hubble sequence + Other types of galaxies o Elliptical galaxies + Classification + Brightness profile + Composition of elliptical galaxies + Dynamics of elliptical galaxies + Indicators of a complex evolution o Spiral galaxies + Trends in the sequence of spirals + Brightness profile + Rotation curves and dark matter + Stellar populations and gas fraction + Spiral structure + Corona in spirals? o Scaling relations + The Tully-Fisher relation + The Faber-Jackson relation + The fundamental plane + The Dn-sigma relation o Black holes in the centers of galaxies + The search for supermassive black holes + Examples for SMBHs in galaxies + Correlation between SMBH mass and galaxy properties o Extragalactic distance determination + Distance of the LMC + The Cepheid distance + Secondary distance indicators o Luminosity function of galaxies + The Schechter luminosity function + The bimodal color distribution of galaxies o Galaxies as gravitational lenses + The gravitational lens effect - Part II + Simple models + Examples for gravitational lenses + Applications of the lens effect o Population synthesis + Model assumptions + Evolutionary tracks in the HRD; integrated spectrum + Star formation history and galaxy colors + Metallicity, dust, and HII regions + Summary + The spectra of galaxies o Chemical evolution of galaxies
Active galactic nuclei
o Introduction + Brief history of AGNs + Fundamental properties of quasars + Quasars as radio sources: synchrotron radiation + Broad emission lines o AGN zoology + QSOs + Seyfert galaxies + Radio galaxies + OVVs + BL Lac objects o The central engine: a black hole + Why a black hole? + Accretion + Superluminal motion + Further arguments for SMBHs + A first mass estimate for the SMBH: the Eddington luminosity o Components of an AGN + The IR, optical, and UV-continuum + The broad emission lines + Narrow emission lines + X-ray emission + The host galaxy + The black hole mass in AGNs o Family relations of AGNs + Unified models + Beaming + Beaming on large scales + Jets at higher frequencies
Clusters and groups of galaxies
* The Local Group o Phenomenology o Mass estimate o Other components of the Local Group * Galaxies in clusters and groups o The Abell catalog o Luminosity function of cluster galaxies o Morphological classification of clusters o Spatial distribution of galaxies o Dynamical mass of clusters o Additional remarks on cluster dynamics o Intergalactic stars in clusters of galaxies o Galaxy groups o The morphology-density relation * X-ray radiation from clusters of galaxies o General properties of the X-ray radiation o Models of the X-ray emission o Cooling flows o The Sunyaev-Zeldovich effect o X-ray catalogs of clusters * Scaling relations for clusters of galaxies o Mass-temperature relation o Mass-velocity dispersion relation o Mass-luminosity relation o Near-infrared luminosity as mass indicator Clusters of galaxies as gravitational lenses
* Luminous arcs * The weak gravitational lens effect